Turning antagonists into allies: Bacterial-fungal interactions enhance the efficacy of controlling wilt disease.

Intense microbial competition in soil has driven the evolution of resistance mechanisms, yet the implications of such evolution on plant health remain unclear. Our study explored the conversion from antagonism to coexistence between () and () and its effects on wilt disease (FWD) control. We found a bacilysin transmembrane transporter (MFS4) in , critical during cross-kingdom dialogue with v. Deleting (Δ) mitigated - antagonism, reduced bacilysin import into , and elevated its level in the coculture environment. This increase acted as a feedback regulator, limiting overproduction and enhancing biomass. Δ coinoculation with demonstrated enhanced FWD control relative to wild-type (-WT). In addition, the -WT+ consortium up-regulated antimycotic secretion pathways, whereas the Δ+ consortium enriched the CAZyme (carbohydrate-active enzyme) family gene expression in the rhizosphere, potentiating plant immune responses. This study elucidates the intricacies of bacterial-fungal interactions and their ramifications for plant health.